DE1638969A1 - Method and device for the control of electrical apparatus with the aid of preferably audio-frequency pulses which are superimposed on the power network - Google Patents

Description

Patent attorney Dr. Ing.R. K. Löbbecke

Berlin 37 (Zehlendorf) New street 6

^{T 'L84810i} 1638969

Zellweger A.Gl. Apparatus ··· and machine factories Uster / Sohwei *

Method and device for controlling electrical apparatus with the aid of preferably audio-frequency impulses that are superimposed on the power network *

In what is known as ripple control technology, there are various methods and devices for the transmission of audio-frequency control pulses known in power networks.

In order to be hindered as little as possible by the interference voltages present in the high-voltage networks - despite the greatest possible receiver sensitivity - the so-called reception filters on the receiver side are made as narrow-banded and selective as possible. This great selectivity, however, requires a correspondingly exact match between the transmission and receiver response frequency, which exact match is not easy to achieve in practice. It was therefore proposed ["compare + Patent No. ¹ M ⁶⁹ (request No. 10989/65)], in ripple control systems, both the control frequency on the transmitting side and the receiver response frequency on the receiving side in a rigid relationship to the common network frequency to bind and to let both the control frequency and the receiver response frequency follow all possible changes in the network frequency proportionally.

This known method is very effective and successful. However, it naturally requires a large and expensive outlay in terms of equipment on both the sending and receiving sides as soon as the

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selected control frequency and the corresponding receiver response frequency are not in an integer ratio to the mains frequency.

The present invention avoids this disadvantage and relates to a method for controlling electrical apparatus with the aid of preferably audio-frequency control pulses, which the power network are superimposed, in which the transmission frequency is formed as a mixed product of two frequencies, of which two Frequencies the first has a rigid, integer relationship to the network frequency and the second is independent of the network frequency Has constant value and at which on the receiver side the transmission frequency is initially separated from the mains frequency and then in a mixer is mixed with a frequency, which is also in a rigid integer ratio to the mains frequency stands, whereupon the obtained mixed product is sieved out in a filter, the pass frequency of which is the same, constant, network frequency independent Has value, such as the said second frequency on the transmission side.

The one on both the sending and receiving sides is advantageous Frequency that is not in a rigid relationship to the network frequency is selected to be lower than the network frequency itself.

The present invention also relates to a device for Implementation of the process mentioned and is characterized by a network frequency multiplier each on the transmit and receive side, a mains frequency-independent oscillator on the transmitting side, a mains frequency-independent filter on the receiving side and one mixer each on the transmit and receive side.

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With reference to the figure, the method mentioned and a device for carrying out the same are described below as an example.

It shows the basic structure of the sender and receiver as a block diagram.

1 means the power network common to the transmitter and receiver with the network frequency fjg (e.g. 50 Hz).

The transmitter 2 and the receiver 3 are connected to the power network 1.

In so-called Ilund control systems there are normally a large number of receivers 3 available.

In the transmitter 2 is first a frequency multiplier 21 a first voltage is generated, the frequency f j of which is an integer multiple. times β of the network frequency fj ^. So

fj = η χ fpf

In an auxiliary oscillator 22, a second voltage is generated at the same time, the frequency f £ of which is as constant as possible and independent of the network frequency. For reasons explained later, it is advantageous to choose the frequency i> 2 as small as possible, that is to say less than the network frequency f ^.

The two frequencies fj and £ 2 are mixed in a mixer 23. For example, the sum frequency (fj + £ 2) of the mixed products produced in it can be screened out in a filter 24 and further used _{as the transmission frequency f g.} For this purpose, the voltage is _{amplified with the frequency f s} = fj + i ^ in an amplifier and then, for example, in the form of control pulses via a pulse switch 4, a tuning coil 5 and a coupling capacitor 6, superimposed on the power network 1 in a known manner. Thereby controls

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the command device 7 according to the control commands to be transmitted also known to be the pulse switch 4.

The coding of the control pulses can, for example, according to the pulse interval, be carried out according to the number of pulses or the pulse duration method.

The control pulses with the frequency f _g reach the receiver 3 via the power network 1. Here, they are advantageously separated in a prefilter 31 with the pass _{frequency f s} from the power current with the frequency f ^. The bandwidth of the prefilter 31 is deliberately chosen so large that its transmission attenuation is practically not influenced _{by the fluctuations in the control frequency f g that are possible in practice.}

The greatest possible fluctuations in the control frequency f _{g are} practically given by the greatest possible fluctuations in the network frequency fjy and in percentage terms are approximately the same as the percentage fluctuations in the network frequency fjvj. This is because:

^f s ^{= f} l ^{+ f} 2 * ^nxf N ^{+ f} 2 '

where η is a whole, unchangeable number and where f2 », as explained earlier, is an auxiliary frequency that is as constant as possible and as small as possible. The fluctuations in the auxiliary frequency f «as a result of temperature changes, aging, etc. can be kept in the order of magnitude of + ^ 1% o without great effort. Furthermore, since f ^ is generally at least 10 times smaller than η χ f _n , these fluctuations only have an effect of jk 0.1% o on the control frequency f ₆ . In contrast, network frequency fluctuations of + 1 to 4% must always be expected. The practically possible fluctuations in the frequency f2 can therefore be neglected compared to the practically possible fluctuations in the network frequency% and the frequency fj

will. 009845/0468 \ _{ΛΛ M.}

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In the frequency multiplier 32 - which is expediently built exactly the same as the frequency multiplier 21 - a voltage with the frequency fj ¹ = η χ fjj is generated.

The two voltages with frequencies f * 'and f become one Mixer 33 is supplied, in which, among other things, a voltage with the frequency

^l 2 ¹ S ¹ I

arises.

In a main filter 34 the frequency is f 'of all others Frequencies separated, this main filter 34 being very narrow-band and can be made selective. The receiver 3 is thus on the desired reception frequency

^f E ⁼ V ⁺ V ^{= f} l ^{+ f} 2 ■ ^f s

Voted.

The frequency f2 * can then be amplified in an amplifier 35 and an evaluation circuit 36 are supplied.

It is advisable to check the length of the control pulses at the frequency f ₂ ', for example in the evaluation circuit 36 before the actual decoding, and to only process those control pulses that arrive at the Auewerter 36 without interruption for a given duration. This can prevent voltage surges occurring in the network from simulating control pulses and thereby causing incorrect switching.

Such Spannungeetöeee can namely> though greatly weakened - go to the main filter 34 and the same undesirable

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Initiate vibrations with the frequency f «'. This - by push Excited vibrations, however, subside relatively quickly and cannot cause incorrect switching if the. Evaluation circuit 36, as mentioned, does not respond to short or interrupted pulses reacted.

In the following, some considerations about the minimum permissible bandwidth of the main filter will now be based on a practical example 34 made.

As mentioned at the beginning, there is a great deal of interest in the resulting To make the reception bandwidth as small as possible so that the receiver can respond to the interference voltages present in all power networks of all kinds - despite the greatest possible receiver sensitivity - do not react with incorrect switching.

The minimum bandwidth is first - according to information theory - given by the amount of information to be transmitted per unit of time.

In ripple control systems, the amount of information is now per unit of time very small in most cases. You can therefore work with relatively long control pulses from this point of view. In practice, control pulses with a duration of 1 to 10 seconds are common.

This results in minimum bandwidths of approx. 1 to 0.1 Hz.

If you now decide on a bandwidth of, for example, 0.2 Hz, the transmission frequency and the receiver pass-through frequency must always match with an accuracy of at least 0.1 Hz. With a control frequency of 1023 Hz, for example, this results in a minimum accuracy of + 0.05 % q. This accuracy and constancy is for example. With a mechanical or electrical filter, which directly

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is tuned to the frequency of 1023 Hz, at an economically acceptable expense and in the required temperature range of, for example.

- 20 ⁰ C to + 60 ⁰ C cannot be realized with sufficient certainty.

When the method according to the invention is used, this arises in this regard - as will be explained in the following - but no difficulties whatsoever.

The transmission frequency f _s of, for example, 1023 Hz can namely - as described - be formed from the 20th network harmonic (n = 20, i.e. ίχ = 20 χ 50 = 1000) and a constant frequency of 23 Hz.

The receiver response frequency is also obtained from the 20th network harmonic (i.e. fj ¹ = 20 χ 50 = 1000) and from the pass frequency Ϊ2 * of a band filter with a nominal frequency of 23 Hz.

Of the control _{frequency f s} and the receiver response frequency fg, the components f ·· and f ^ 'are rigidly linked to the network frequency f] \ j, fj and f ^ ¹ are therefore identical regardless of the network frequency fjj, so that the Control and receiver response frequency

- Even with large fluctuations in the network frequency f _N - no deviations can arise.

The two frequencies fj and f- ^ ¹ can also not be caused by temperature or aging-related fluctuations in any electrical properties of the components of the frequency multiplier 21, respectively. 32 can be influenced. This leaves only the possible deviations in the frequency f _{2 of} the oscillator 22 in the transmitter and the possible deviations in the pass _{frequency f 2} 'of the filter 34 in the receiver.

These deviations can now be on the sending as well as the receiving side

- without great effort - each within the limits + _ 1% o of 23 Hz, d. H. each be kept within _ + 0.023 Hz.

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This results in a maximum possible deviation between the send and Reception frequency of 0.046 Hz, which, as mentioned above, with a Bandwidth of 0.2 Hz is still easily bearable.

From what has been said it is also clear that - in order to get the smallest possible differences overall - the Frequency fj / fj 'advantageously as high as possible and the frequencies 'advantageously selects as small as possible.

The design of the detailed circuits in the individual blocks of the figure can be carried out according to the state of the art.

It is advantageous for the frequency multipliers 21 and 32 To use circuits that essentially correspond to those described in + Patent No. (Application No. 12940/65).

The main filter 34 can, for example, be designed as a mechanical filter or as an electrical filter as explained in + Patent No. (Application No. 14576/65).

With regard to the detailed execution of the evaluation circuit 36 is finite to the + patents nos. 369 * 187 and 393 * 491.

+ Switzerland.

Claims;

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0.9 845/0468. BADORiGINAI,

Claims (1)

Pat e η t a η s sprohe ι Method for controlling electrical equipment with the aid of preferably tone-frequency control pulses * the power grid. are superimposed, d u r c h gekennzei e h η e t that the transmission frequency (f) is formed as a mixed product (f.j + f ₂ ) from two frequencies (f ^ and f ₂ ), of which »two frequencies (f ^ and fp) the first · (f ^) in a rigid integer ratio (n) to Mains frequency (f ") and the second (fp) has a constant value that is independent of the mains frequency, and that on the receiver side the transmission frequency (f.) Is initially separated from the mains frequency (f") and then in a secondary stage (33) with a frequency (f ₁ · } is mixed, which frequency Cf ₁ *) is also in a rigid, integer ratio to the network frequency (f «), whereupon the mis egg product obtained is sieved out in a filter (34), the throughput frequency of which has the same, constant network frequency-independent value (f ₂ * ), like the said second frequency (f ₂ ) on the transmitting side. 2, the method according to claim 1, characterized in that the characterizing chnet that the portion (fp) of the transmission frequency (f_), which is not rigidly connected to the network frequency (fjj) is tied, less than the grid frequency (f ^) is chosen by oneself, 3 * device for performing the method according to claim 1 and 2, characterized by - 10 -009845/0408 ^ D original - ίο - a network frequency multiplier (2t, 32) each on the transmitting and receiving side, a network frequency-independent oscillator (22) on the transmitting side, a network frequency-independent filter (34) on the receiving side and one each
Miechstufe (23t 33) on the sending and receiving side